Printer with printhead assembly, clutch assembly, and printer ribbon transport assembly

ABSTRACT

A printer may include a printhead assembly a clutch assembly, and/or a printer ribbon transport assembly. The printhead assembly may include a printhead biasing assembly defining a biasing ramp which may be configured to apply a biasing force to a printhead support bracket so as to at least partially counteract a ribbon force. The clutch assembly may be configured to supply or take-up a printer ribbon with first and second spool engagement members of different diameters that frictionally engage first and second friction members. The printer ribbon transport assembly may include a rotation lock mechanism configured to prevent rotation of a ribbon take-up core when the take-up core is disengaged from a drive assembly so as to prevent a loss in ribbon tension.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Non-Provisional applicationSer. No. 13/284,540, filed Oct. 28, 2011, now issued as U.S. Pat. No.8,882,371, which claims the benefit of U.S. Provisional Application No.61/407,654, filed Oct. 28, 2010, all of which are hereby incorporated byreference.

FIELD OF THE INVENTION

Embodiments of the invention relate to printers and assembliesincorporated into the same. For example, various embodiments of theinvention relate to thermal transfer printers that are configured toprint to labels or other media using an ink donor ribbon supply that issupported by ribbon clutch and transport assemblies, and a thermaltransfer printhead assembly.

DESCRIPTION OF RELATED ART

Conventional thermal transfer printers include various components andassemblies such as a ribbon supply assembly, a ribbon take-up assembly,a media support assembly, a platen assembly, and a printhead assembly.During printing operations, the media is drawn from the media supportassembly and ribbon is drawn from the ribbon supply assembly. Each ofthe ribbon and media are then fed through a nip defined between theprinthead assembly and the platen assembly. Elements within theprinthead assembly are heated to transfer ink from the donor ribbon tothe media thereby creating printed indicia.

Applicant has identified a number of deficiencies and problemsassociated with the manufacture, use, operation, and maintenance ofconventional thermal transfer printers. Through applied effort,ingenuity, and innovation, Applicant has solved many of these identifiedproblems by developing a solution that is embodied by the presentinvention, which is described in detail below.

BRIEF SUMMARY OF THE INVENTION

Various embodiments of the present invention are directed to assembliesand components that are used in printers such as thermal transferprinters. More particularly, embodiments of invention are directed to aprinter ribbon transport assembly, a clutch assembly usable with a printribbon or other media, and a printhead assembly.

An example embodiment of the present invention may include a printheadassembly for use in a printing apparatus. The printhead assembly mayinclude a printhead and a printhead support bracket. The printheadsupport bracket may include an opposed ramp surface configured forengagement by a biasing ramp of the printing apparatus and a ribbon peelsurface configured to receive a ribbon force. The opposed ramp surfacemay be configured to receive a biasing force from the biasing ramp andthe biasing force may at least partially counteract the ribbon force.The opposed ramp surface may define an angle of between 10 and 25degrees relative to the major surface of the printhead support bracket.

Embodiments of the printing apparatus may also include a printheadbiasing assembly including a printhead biasing element configured tobias the biasing ramp into contact with the opposed ramp surface of theprinthead support bracket. The printhead biasing assembly may alsoinclude a guide member configured to guide the biasing ramp on a guidepath. The guide path may be configured to direct the biasing ramp towarda platen. The biasing ramp may include a removable wedge. The printheadassembly may further include a heat sink, where the heat sink is coupledbetween the printhead and the printhead support bracket. The biasingassembly may be configured to bias the heat sink into contact with astop member. The stop member may be defined by a base structure. Theprinthead assembly may be a replaceable component of the printingapparatus.

Embodiments of the present invention may provide a method of aligning aprinthead. The method may include receiving a ribbon force at a peelsurface of a printhead support bracket and generating a biasing force atthe printhead support bracket to at least partially counteract theribbon force. The biasing force may be directed by a biasing ramp of abiasing assembly engaging an opposed ramp surface of the printheadsupport bracket. The biasing force may be directed at an angle between10 and 25 degrees relative to the printhead support bracket. The methodmay also include engaging a stop member with a heat sink coupled to theprinthead. The method may still further include maintaining asubstantially consistent ribbon force with a first clutch mechanismconfigured to engage a ribbon supply spool and a second clutch mechanismconfigured to engage a take-up spool. The method may also includeguiding the biasing ramp on a guide path with a guide member of thebiasing assembly. Optionally, the method may include directing thebiasing ramp toward a platen with the guide member.

Example embodiments of the present invention may include a system forprinting, including a printing apparatus configured to print on media, aprinthead, and a printhead support bracket. The printhead supportbracket may include an opposed ramp surface configured for engagement bya biasing ramp of the printing apparatus and a ribbon peel surfaceconfigured to receive a ribbon force. The opposed ramp surface may beconfigured to receive a biasing force from the biasing ramp, where thebiasing force at least partially counteracts the ribbon force. Theprinting apparatus may include a printhead biasing assembly including abiasing element configured to bias the biasing ramp into contact withthe opposed ramp surface of the printhead support bracket. The printheadbiasing assembly may include a guide member configured to guide thebiasing ramp on a guide path. The guide path may be configured to directthe biasing ramp toward a platen of the printing apparatus. The biasingramp may include a removable wedge.

Example embodiments of the present invention may include a printerribbon transport assembly. The printer ribbon transport assembly maycomprise a take-up spool assembly having a take-up core that isconfigured to receive a ribbon, and wherein the take-up spool assemblyis configurable between an engaged position and a disengaged position.The printer ribbon transport assembly may further comprise a driveassembly configured to drive the take-up spool assembly to rotate thetake-up core in a first direction when the take-up spool assembly isdisposed in the engaged position, and a rotation lock mechanismconfigured to prevent rotation of the take-up core in a seconddirection, which is opposite to the first direction, when the take-upspool assembly is disposed in the disengaged position. In oneembodiment, the take-up spool assembly may comprise a take-up clutchassembly configured to bias the take-up core in the first direction.

In some embodiments, the rotation lock mechanism may comprise a ratchetassembly. The ratchet assembly may comprise a pawl configured to engagea toothed wheel that is rotationally connected to the take-up spoolassembly. A spring or other biasing element may be configured to biasthe pawl to engage the toothed wheel when the take-up spool assembly isin the disengaged position. The rotation lock mechanism may furthercomprise a lever arm coupled to the pawl and configured to cause thepawl to disengage from the toothed wheel when the take-up spool assemblyis in the engaged position.

The printer ribbon transport assembly structured in accordance withvarious embodiments may further comprise a lever engagement surface,wherein the lever arm is configured to engage the lever engagementsurface when the take-up spool assembly is in the engaged position. Therotation lock mechanism and the take-up spool assembly may be mounted toa lid, and the drive assembly may be mounted to the base structure.Further, the base structure may define the lever engagement surface, andthe lever arm may be configured to release from the lever engagementsurface when the take-up spool assembly is in the disengaged position.

Still other embodiments are directed to a clutch assembly comprising afirst spool engagement member defining a first diameter and a firstfriction member configured to frictionally engage the first spoolengagement member. A second spool engagement member may define a seconddiameter that is larger than the first diameter. Further, the clutchassembly may include a second friction member configured to frictionallyengage the second spool engagement member.

Still further embodiments of the present invention are directed to aclutch assembly comprising a first spool engagement member defining afirst friction torque and a first friction member configured tofrictionally engage the first spool engagement member. A second spoolengagement member may define a second friction torque that is largerthan the first friction torque. Further, the clutch assembly may includea second friction member configured to frictionally engage the secondspool engagement member.

In some embodiments the clutch assembly may further comprise a biasingassembly configured to bias the first spool engagement member intocontact with the first friction member and bias the first frictionmember into contact with the second friction member. Further, the secondspool engagement member may be configured to couple to the firstfriction member. The first friction member may comprise an integralmember in some embodiments. In other embodiments the first frictionmember may comprise a friction plate and a coupling plate keyed thereto,wherein the coupling plate is configured to couple the friction plate tothe second spool engagement member.

In some embodiments the clutch assembly may be configured to take-up aribbon. In such embodiments the clutch assembly may further comprise adriven member configured to rotationally engage a drive assembly andfurther configured to engage a coupler. Further, a biasing element suchas a spring may be coupled to the coupler and the second frictionmember. Rotation of the drive assembly may be configured to rotate thedriven member so as to impart a rotational force to the second frictionmember and thereby cause the second friction member to rotate. Thereby,rotation of the second friction member may be configured to cause thefirst friction member to rotate via frictional engagement, and rotationof the first friction member may be configured to cause the first spoolengagement member to rotate via frictional engagement. Also, rotation ofthe first friction member may be configured to rotate the second spoolengagement member via coupling there between.

In other embodiments the clutch assembly is configured to supply aribbon. In such embodiments the first friction member may be configuredto rotate when the first spool engagement member rotates via frictionalengagement there between and further configured to rotate when thesecond spool engagement member rotates via coupling there between. Also,the first friction member may be configured to rotate the secondfriction member via frictional engagement there between. The clutchassembly may further comprise a coupler configured to couple to thesecond friction member through a biasing element such as a spring,wherein the coupler is configured to couple to a stationary member.Thereby, rotation of the second friction member may be configured torotate the biasing element via coupling there between, and the biasingelement may be configured to resist movement of the second frictionmember via coupling to the stationary member though the coupler.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

Having thus described the invention in general terms, reference will nowbe made to the accompanying drawings, which are not necessarily drawn toscale, and wherein:

FIG. 1 illustrates a perspective view of a printer structured accordingto various embodiments of the invention;

FIG. 2 illustrates a perspective view of the printer of FIG. 1 with alid removed for illustration purposes;

FIG. 3 illustrates an enlarged section and perspective view of aprinthead assembly structured in accordance with embodiments of theinvention, taken along section line 3-3 of FIG. 1;

FIG. 3A illustrates an enlarged partial sectional view of a printerribbon path extending through a printhead assembly structured inaccordance with embodiments of the invention, taken along section line3-3 of FIG. 1;

FIG. 4 illustrates an enlarged sectional view of a printhead assemblyhaving a stop member according to one embodiment of the invention, takenalong section line 4-4 of FIG. 1;

FIG. 5 illustrates ribbon supply and take-up clutch assembliesstructured in accordance with embodiments of the invention, and ribbonsupply and take-up spools, each originally shown proximate detail circle5 of FIG. 2 but shown in FIG. 5 as removed from the printer forillustration purposes;

FIG. 6 illustrates an exploded view of the ribbon supply clutch assemblyof FIG. 5;

FIG. 7 illustrates an exploded view of the ribbon take-up clutchassembly of FIG. 5;

FIG. 7A illustrates a perspective view of the ribbon take-up clutch ofFIG. 7 with a ribbon take-up core attached to a first spool engagementmember according to an embodiment of the invention;

FIG. 7B illustrates a perspective view of the ribbon take-up clutch ofFIG. 7A with a ribbon take-up core attached to a second spool engagementmember according to an embodiment of the invention;

FIG. 8 illustrates a sectional view of a printer ribbon transportassembly according to one embodiment of the invention, taken alongsection line 8-8 of FIG. 1;

FIG. 9A illustrates a detail view of the printer ribbon transportassembly according to one embodiment of the invention, taken alongdetail circle 9AB of FIG. 8 and illustrated with the lid is in a closedconfiguration; and

FIG. 9B illustrates a detail view of the printer ribbon transportassembly of FIG. 8, taken along detail circle 9AB and illustrated withthe lid in an open configuration.

DETAILED DESCRIPTION OF THE INVENTION

The present invention now will be described more fully hereinafter withreference to the accompanying drawings, in which some, but not allembodiments of the invention are shown. Indeed, the invention may beembodied in many different forms and should not be construed as limitedto the embodiments set forth herein; rather, these embodiments areprovided so that this disclosure will satisfy applicable legalrequirements. Like numbers refer to like elements throughout.

FIG. 1 illustrates a perspective view of a printer 100 according to anexample embodiment of the invention. The printer 100 may include avariety of components and assemblies configured to facilitate printingon a print media. In some embodiments the print media may compriselabels that are releasably adhered to a carrier media. Thereby, forexample, a spool of print media may be employed to support such labelsas needed. In some embodiments, the printer 100 may employ a ribbon(e.g., an ink donor or thermal transfer ribbon) to print on the printmedia. For example, the printer 100 may be a thermal transfer printerthat selectively heats the ribbon using a printhead in order to transferink from the ribbon to the print media.

Various embodiments are directed to a printer 100 comprising a number offeatures configured to facilitate printing. The depicted printer 100comprises a lid 102 and a base structure 104. The base structure 104, asused herein, may refer to the bottom portion or frame of the printer 100below the lid 102 as well as various internal structures that supportthe components of the printer. The lid 102 may be configured to pivotvia a hinge 106 or other mechanism so as to allow a user to accessinternal components of the printer 100. For example, a user may be ableto replace the ribbon, the print media, and other consumable supplies asneeded.

FIG. 2 illustrates a perspective view of the printer 100 with the lid102 removed in order to illustrate internal components therein. Asillustrated, the printer 100 may be configured to receive print media108, which may be stored on a print media spool 110, although variousother configurations and types of print media may be employed in otherembodiments that may not be supported by a spool as may be appreciatedby one of ordinary skill in the art (e.g., folding media, stacked media,etc.). A printer ribbon transport assembly 112 may in some embodimentscomprise a ribbon supply spool 116, a ribbon take-up spool 120, a ribbonsupply clutch assembly 122, a ribbon take-up clutch assembly 124, and adriven member 170 (driven by drive assembly 172 shown in FIG. 8 anddescribed further below). The printer ribbon transport assembly 112 maybe configured to direct a ribbon 114 from the ribbon supply spool 116over or through a printhead assembly 118 to the ribbon take-up spool120. The ribbon take-up spool 120 may comprise a ribbon take-up core120A, 120B (see, e.g., FIGS. 7A and 7B) on which the ribbon 114 isreceived. The ribbon supply clutch assembly 122 and the ribbon take-upclutch assembly 124 may be configured to improve movement of the ribbon114 and, thus, improve printer performance, as will be described below.

Printhead Biasing Assembly

As mentioned above, ink from the ribbon 114 may be transferred onto theprint media 108 using a printhead assembly 118. Details concerning aprinthead assembly 118 structured in accordance with one embodiment areillustrated in FIG. 3. The depicted printhead assembly 118 may comprisea printhead 126, a platen 130, a printhead biasing assembly 132, and aprinthead support bracket 134. The printhead 126 may in one embodiment,as further illustrated in FIG. 3A, be configured to heat the ribbon 114so as to transfer ink from the ribbon to the print media 108. In thisregard, from the perspective shown, the ribbon 114 and print media 108may travel generally from the left to right and enter a nip 128 formedbetween the printhead 126 and the platen 130. The platen 130 may bedriven (i.e., driven to rotate by a motor or other drive means) in someembodiments so as to pull the print media 108 through the nip 128.Further, as will be discussed below, the ribbon take-up spool 120 mayalso be driven so as to pull the ribbon 114 from the ribbon supply spool116 through the nip 128 and onto the ribbon take-up spool 120, where theused ribbon is collected. In still another embodiment, the ribbontake-up spool 120 and the ribbon supply spool 116 may each be drivenwith the ribbon take-up spool 120 having a relatively greater driveforce and/or velocity when compared to the ribbon supply spool 116 so asto ensure that appropriate tension is applied to the ribbon.

The printhead biasing assembly 132 may be configured to bias theprinthead 126 into a desired position with respect to the platen 130.The depicted printhead biasing assembly 132 comprises a biasing elementin the form of a spring 139, a biasing member 140, and a biasing ramp138 extending from the biasing member 140. The depicted biasing ramp 138defines a wedge that is attached to a biasing member 140. However, inother embodiments, the biasing ramp 138 may be integrally formed withthe biasing member 140 and, thus, define a single-piece unit.

In some embodiments, the printhead 126 may be supported by a printheadsupport bracket 134. The depicted printhead 126 is configured to attachto the printhead support bracket 134 via a heat sink 136. In oneembodiment, the printhead support bracket 134 defines an opposed ramp142, which is also generally wedge shaped, that is positioned forengagement by the biasing ramp 138 of the printhead biasing assembly132.

The spring 139 of the printhead biasing assembly 132 is configured tobias the biasing ramp 138 into contact with the opposed ramp 142 of theprinthead support bracket 134. In some embodiments, the printheadassembly 118 may further comprise a guide member 144 configured to guidethe biasing ramp 138 and the printhead biasing assembly 132 on a guidepath. The guide member 144 may comprise part of the base structure 104and/or printer frame structure in some embodiments. For example, in theillustrated embodiment, the guide member 144 is formed as a slot isdisposed within a frame member extending from the base structure 104;however, the guide member 144 does not necessarily contact the biasingramp 138 directly. For example, the biasing ramp 138 may be arranged ona carrier, such as biasing member 140, which is guided within the guidemember 144. Further, the direction with which the biasing member 140 isbiased may be generally in the direction of the platen roller 130 togenerate a biasing force of the printhead 126 against the platen roller130 along nip 128. This biasing force, together with the biasing ramp138 and the opposed ramp 142 bias the printhead 126 generally toward theplaten roller 130 and forward along the media path, toward the bullnose146.

The biasing ramp 138 of the printhead biasing assembly 132 may beconfigured to apply a biasing force to the printhead support bracket 134through the opposed ramp 142. The biasing force, in some embodiments,may have at least two components, i.e., a first or downward componentthat operates to drive the printhead 126 downwardly into the platen 130,and a second or lateral component that operates to drive the printheadsupport bracket 134 generally forwardly against an applied ribbon forceRF, which is illustrated in FIG. 3A. As will be appreciated by one ofordinary skill in the art, the ramp may be a block, wedge, or othercomplex shape that directs the biasing force in a direction thatsubstantially opposes the applied ribbon force RF.

FIG. 3A is a detail view of the path of a ribbon 114 through theprinthead assembly 118 of a printer structured in accordance withvarious embodiments of the invention. The ribbon 114 is drawn from theribbon supply spool 116 between the nip 128 defined by the printhead 126and the platen 130, over a bullnose or ribbon peel surface 146 definedby the printhead support bracket 134, and returned upwardly to theribbon take-up spool 120. As will be appreciated by one of skill in theart in view of this disclosure, tension in the ribbon 114 may tend toapply a ribbon force RF to a ribbon peel surface 146 of the printheadsupport bracket 134. This force may tend to pull the ribbon supportbracket 134 upwardly and back generally in a direction illustrated byarrow RF in FIG. 3A. In “floating printhead” applications where theposition of the printhead 126 is not rigidly fixed, such a ribbon forceRF can cause misalignment of the printhead 126 and poor print quality.

In various embodiments, the downwardly biased wedge shape of the biasingramp 138 tends to drive the printhead support bracket 134 generallyforwardly (along the media feed path 150) through engagement with theopposed ramp 142. In this regard, the printhead 126 is maintained in aproper print position despite application of the ribbon force RF to theprinthead support bracket 134. Said differently, in some embodiments,the biasing ramp 138 of the printhead biasing assembly 132 may beconfigured to apply a biasing force to the printhead support bracket 134through the opposed ramp 142 that at least partially counteracts theribbon force RF applied by the ribbon 114 to the ribbon peel surface146.

The biasing ramp 138 and the opposed ramp 142 may each define engagementangles between about 10 and 25 degrees relative to the major surface theprinthead support bracket. The angles defined by the biasing ramp 138(e.g., the biasing ramp angle) and the opposed ramp 142 (e.g., theopposed ramp angle) may be selected so as to cause the lateral componentof the biasing force to be directed in a direction so as to at leastpartially overcome the ribbon force RF. For example, when the biasingramp 138 and the opposed ramp 142 define relatively small angles (i.e.,less than 15 degrees), the biasing force may be directed more towardsthe platen 130, whereas relatively sharper angles for the biasing rampangle and the opposed ramp angle (i.e., 30 to 45 degrees) may direct thelateral component of the biasing force to drive the printhead supportbracket 134 generally towards the ribbon peel surface 146, substantiallyalong the media feed path 150.

The biasing ramp 138 and the opposing ramp surface 142 may be locatedproximate a mid-point of the printhead support bracket along the printline defined between the printhead and the platen roller. Positioningthe biasing ramp and opposing ramp surface proximate the mid-point ofthe printhead support bracket may provide an evenly distributed biasingforce against the printhead support bracket along its width. Further,when using center-justified media, positioning the biasing ramp 138 andopposing ramp surface 142 proximate the mid-point may promote an evenlydistributed biasing force along the print-line. A further benefit ofsituating the biasing ramp and the opposing ramp surface proximate themid-point of the printhead support bracket may be to permit wire-harnessconnections to the printhead on both ends of the printhead. Wire harnessconnections at both ends of the printhead may allow for the printhead toreceive print data from either side, which may be beneficial inresistive printheads where the voltage drop increases along the lengthof the printhead away from the harness connector. Wire harnessconnections at both ends of a printhead may also be beneficial as anyforce applied to the printhead via tension of the wire harness may beevenly distributed to both sides of the printhead, thereby bettermaintaining alignment of the printhead with the platen roller.

As illustrated in FIG. 4, in some embodiments, the printhead biasingassembly 132 may be configured to bias a heat sink 136 into contact witha stop member 148 to better align the printhead 126 for printing. Thestop member 148 may be configured to preclude the floating printheadassembly from advancing any further along the media feed path 150.Contact may be achieved and maintained between the stop member and theprinthead assembly in order to maintain a consistent alignment of theprinthead relative to the platen. The heat sink 136 is coupled to theprinthead 126 in order to more efficiently dissipate heat generated atthe printhead, thereby cooling the printhead 126 and generallyincreasing print speed and quality. The printhead assembly 118 may be a“floating printhead” assembly having alignment features similar to thosedisclosed in U.S. patent No. RE 38,473, which was reissued on Mar. 23,2004 and is commonly assigned to the present Applicant, i.e., ZIH Corp.U.S. patent No. RE 38,473 is hereby incorporated by reference in itsentirety.

Dual Clutch Mechanism

FIG. 5 is a detail view of ribbon supply and take-up clutch assemblies122, 124 and ribbon supply and take-up spools 116, 120 structured inaccordance with other embodiments. The depicted ribbon supply clutchassembly 122 and ribbon take-up clutch assembly 124 are configured toimprove and control movement of the ribbon 114 to enhance print quality.The depicted ribbon supply clutch 122 engages the ribbon supply spool116 and the ribbon take-up clutch 124 engages the ribbon take-up spool120. Although operation of the ribbon supply and take-up clutchassemblies 122, 124 are described herein, further features and examplesof the operation of clutch assemblies are provided in U.S. Pat. No.6,637,957, which was issued on Oct. 28, 2003 and is commonly assigned tothe present Applicant, i.e., ZIH Corp. U.S. Pat. No. 6,637,957 is herebyincorporated by reference in its entirety.

As will be described in detail below with respect to FIGS. 6 and 7, theribbon supply clutch assembly 122 and the ribbon take-up clutch assembly124 each comprise first 150, 1150 and second 158, 1158 spool engagementmembers, first 152, 1152 and second 160, 1160 friction members, abiasing assembly 162, 1162, a coupler 166, 1166, and a spring 168, 1168or other biasing element.

Turning specifically to FIG. 6, the first spool engagement member 150 ofthe depicted ribbon supply clutch assembly 122 defines a first frictiontorque, and defines a first diameter D1. The first spool engagementmember 150 may be configured to engage a ribbon spool having a diameterthat corresponds to the first diameter D1 of the first spool engagementmember 150. In one embodiment, the second spool engagement member 158 ofthe ribbon supply clutch assembly 122 may define a second frictiontorque and may define a second diameter D2, where the second frictiontorque is different than the first friction torque and where the seconddiameter is different than the first diameter. The second spoolengagement member 158 may thus be configured to engage a ribbon spoolhaving a diameter that corresponds to the second diameter D2 of thesecond spool engagement member 158. In this regard, as discussed ingreater detail below, the ribbon supply clutch assembly 122 and theribbon take-up clutch assembly 124 may each be configured to engageribbon spools of two differing diameters. The friction torque may beimpacted by the diameter of the ribbon spool, but may also be impactedby the material and surface finish of the material contained on theribbon spool. For example, materials with a high coefficient of frictionon their surface may require a higher friction torque to dispensematerial from the spool.

In one embodiment, the first spool engagement member 150 is positionedadjacent the first friction member 152. The depicted first frictionmember 152 comprises a friction plate 154 for frictionally engaging thefirst spool engagement member 150 and a coupling plate 156 keyed (i.e.,mechanically interlocked as by the depicted key 153 and cavity 151structures) thereto. In other embodiments, the first friction member 152may be one integrally formed part.

The depicted first friction member 152 is configured to couple to thesecond spool engagement member 158 via fasteners 155 (e.g., flanges ortabs) defined in the coupling plate 156 as shown. The depicted secondfriction member 160 is configured to frictionally engage the firstfriction member 152, i.e., the coupling plate 156 of the first frictionmember, to thereby indirectly frictionally engage the second spoolengagement member 158 therethrough.

Frictional engagement of the various clutch assembly components may beassisted by a biasing assembly 162 that is configured to bias the firstspool engagement member 150 into contact with the first friction member152 (i.e., the friction plate 154) and further configured to bias thefirst friction member 152 (i.e., the coupling plate 156) into contactwith the second friction member 160. In one embodiment, the first spoolengagement member 150 may comprise a lip 164 that the biasing assembly162 seats against (perhaps through the use of a gasket or washer) inorder to bias the first spool engagement member 150 into contact withthe first friction member 152 (i.e., the friction plate 154) and furtherconfigured to bias the first friction member 152 (i.e., the couplingplate 156) into contact with the second friction member 160. The biasingassembly 162 may include a fastener (i.e., a screw as shown) that isadapted to engage and retain the second friction member 160 via, forexample, a threaded hole defined by hub 161.

The above mentioned features may be (though they need not necessarilyhave to be) common to both the ribbon supply clutch assembly 122 and theribbon take-up clutch assembly 124 as illustrated in FIGS. 6 and 7.However, the ribbon supply clutch 122 may function in a slightlydifferent manner than the take-up clutch assembly 124 to betterfacilitate paying out of the ribbon 114. In this regard, as illustratedin FIG. 6, the first friction member 152 may be configured to rotatewhen the first spool engagement member 150 or the second spoolengagement member 158 rotates as ribbon 114 is pulled (i.e., via thedriven take-up spool) from the ribbon supply spool 116. For example, thefirst friction member 152 (i.e., the friction plate 154) may rotate viafrictional engagement with the first spool engagement member 150. By wayof further example, the first friction member 152 (i.e., the couplingplate 156) may be configured to rotate when the second spool engagementmember 158 rotates via the coupling therebetween. Further, the firstfriction member 152 (i.e., the coupling plate 156) may be configured torotate the second friction member 160 via frictional engagementtherebetween. Accordingly, when the ribbon supply spool 116 impartsrotary motion to either of the first spool engagement member 150 or thesecond spool engagement member 158, this motion may be transferred tothe first friction member 152 and the second friction member 160.

The ribbon supply clutch assembly 122 may further comprise a coupler 166configured to couple to the second friction member 160 through a biasingelement such as a spring 168. The spring 168 may comprise a torsionspring in some embodiments. Further, the coupler 166 may be configuredto couple to or be supported by a stationary member such as, forexample, the base structure 104. Rotation of the second friction member160 may be configured to rotate the spring 168 via coupling therebetween, and the spring may be configured to resist movement of thesecond friction member via the coupling to the stationary member (i.e.,the base structure 104) through the coupler 166. Accordingly, motionimparted to the first spool engagement member 150 or the second spoolengagement member 158 by the ribbon 114 being pulled or drawn from theribbon supply spool 116 may be subjected to resistance created byfrictional engagement between the first friction member 152 and thefirst spool engagement member 150 and/or frictional engagement betweenthe second spool engagement member 158 and the second friction member160. Further, the spring 168 may operate to gradually increase theresistance force directed counter to the rotation until slippage of thefirst friction member 152 and/or second friction member 160 occurs. Inthis way, ribbon may be drawn from supply spool at a smooth andgradually increasing tension rather than at an abrupt, jerky, andinconsistent tension. In addition, consistency in the tension betweenthe supply spool and the take-up spool may be maintained regardless ofwhether the spools are large or small. Further, when media is reversedwithin along media feed path 150, the torsion spring 168 may function tomaintain tension across the ribbon web. Turning now to FIG. 7, anembodiment of the ribbon take-up clutch assembly 124 configured totake-up the ribbon 114 with the ribbon take-up spool 120 is illustrated.As noted above, many of the components of the take-up clutch assembly124 may be similar to those described above with respect to the supplyclutch assembly 122, and hence these components will not be discussed indetail. However, the ribbon take-up clutch assembly 124 may furthercomprise a driven member 170 (see, e.g. FIG. 2) configured torotationally engage a drive assembly 172 (see, e.g. FIG. 8) and furtherconfigured to engage the coupler 1166. For example, in the illustratedembodiment, the driven member 170 (not shown in FIG. 7) comprises a gearthat is integral with the coupler 1166. However, in other embodimentsthe driven member 170 may otherwise be coupled or attached to thecoupler 1166.

Thus, rather than receiving motion from a driven ribbon spool, thetake-up clutch assembly 124 may be configured to receive rotary motionfrom the drive assembly 172 through the driven member 170. Accordingly,the coupler 1166 may rotate. Instead of engaging the second frictionmember 1160 directly, the coupler 1166 may in some embodimentsindirectly engage the second friction member 1160. For example, thecoupler 1166 may engage a spring 1168 that is coupled to the secondfriction member 1160. The spring 1168 may comprise a torsion spring insome embodiments. Thereby, rotation of the coupler 1166 may transferrotary force to the second friction member 1160 through the spring 1168,which may in turn transfer rotary force to the first friction member1152 (i.e., the coupling plate 1156).

Thus, rotation of the first friction member 1152 may be configured tocause the first spool engagement member 1150 to rotate via frictionalengagement with the friction plate 1154. Further, rotation of the firstfriction member 1152 may be configured to rotate the second spoolengagement member 1158 via coupling through the coupling plate 1156.Accordingly, both the first spool engagement member 1150 and the secondspool engagement member may be rotated so as to pull the ribbon 114 fromthe ribbon supply spool 116 and receive the ribbon at the ribbon take-upspool 120. The above-described frictional engagements may allow for someslippage within the take-up clutch assembly 124 and further the spring1168 may create a biasing force that increases when the driven member170 is driven so as to reduce abrupt changes in force on the ribbon 114(i.e., to reduce or eliminate spikes or abrupt changes in the tension ofthe ribbon or the rotational speed supply or take-up cores). Further,the spring 1168 may function to maintain tension on the ribbon 114 whenthe take-up clutch assembly 124 is not being driven, which can behelpful for preventing previously wound ribbon for backing off its core.

As discussed above, in one or both of the ribbon supply clutch assembly122 and the ribbon take-up clutch assembly 124, the second spoolengagement member 158, 1158 may define a second diameter D2, D2′ that isdifferent from the first diameter D1, D1′ of the first spool engagementmember 150, 1150. In the depicted embodiments, the second spoolengagement member 158, 1158 defines a second diameter D2, D2′ that islarger than the first diameter D1, D1′ of the first spool engagementmember 150, 1150. Accordingly, in one embodiment the second spoolengagement member 158, 1158 may be configured to engage a ribbon coreapproximately of the second diameter D2, D2′, and the first spoolengagement member 150, 1150 may be configured to engage a ribbon coreapproximately of the first diameter D1, D1′. Thus, the ribbon supplyclutch assembly 122 and the ribbon take-up clutch assembly 124 may beconfigured to engage ribbon cores of both the first diameter D1, D1′ andthe second diameter D2, D2′, and hence the printer 100 may be configuredto receive different diameters of ribbon cores. Similarly, in one orboth of the ribbon supply clutch assembly 122 and the ribbon take-upclutch assembly 124, the second spool engagement member 158, 1158 maydefine a second friction torque that is different from the firstfriction torque of the first spool engagement member 150, 1150. In thedepicted embodiments, the second spool engagement member 158, 1158defines a second friction torque that is larger than the first frictiontorque of the first spool engagement member 150, 1150. Accordingly, inone embodiment the second spool engagement member 158, 1158 may beconfigured to engage a ribbon core that requires a second frictiontorque, and the first spool engagement member 150, 1150 may beconfigured to engage a ribbon core that requires a first frictiontorque. Thus, the ribbon supply clutch assembly 122 and the ribbontake-up clutch assembly 124 may be configured to engage ribbon cores ofboth the first friction torque and the second friction torque, and hencethe printer 100 may be configured to receive different ribbon spoolsrequiring different friction torques for dispensing of the ribbon.

In this regard, FIGS. 7A and 7B illustrate the ribbon take-up clutchassembly 124 engaging ribbon take-up cores 120A, 120B on which theribbon 114 may be collected to form the ribbon take-up spool 120. InFIG. 7A the take-up clutch assembly 124 is depicted engaging a ribbontake-up core 120A with the first spool engagement member 1150. Theribbon take-up core 120A may define a diameter DS1 that is substantiallythe same as the diameter D1′ of the first spool engagement member 1150.Conversely, as illustrated in FIG. 7B, the take-up spool assembly 124may be configured to engage a ribbon take-up core 120B with a relativelylarger diameter DS2 than the diameter DS1 of a ribbon take-up core 120Athat is engaged by the first spool engagement member 1150. Thus, theribbon take-up core 120B may engage the second spool engagement member1158. The ribbon take-up core 120B may define a diameter DS2 that issubstantially the same as the diameter D2′ of the second spoolengagement member 1158. Note that the ribbon supply clutch assembly 122may in some embodiments engage a relatively smaller ribbon supply spooland a relatively larger ribbon supply spool in substantially the samemanner as depicted in FIGS. 7A and 7B.

Clutch Locking Mechanism

FIG. 8 depicts a printer ribbon transport assembly 112 structured inaccordance with another embodiment. The depicted printer ribbontransport assembly 112 comprises a ribbon supply spool 116, a ribbonsupply clutch assembly (not shown), a drive assembly 172, a take-upspool assembly 174, and a rotation lock mechanism 178. The driveassembly 172 comprises a plurality of gears including a pinion gear 176that is driven by a motor (not shown). The depicted take-up spoolassembly 174 comprises a ribbon take-up spool 120 and a ribbon take-upclutch assembly (not shown).

Turning to FIG. 9A, which is a detail view taken along detail circle 9ABof FIG. 8, the depicted rotation lock mechanism 178 comprises a pawl180, a toothed wheel 182 configured to be engaged by the pawl, a spring186 (or other biasing element), and a lever arm 188, as will bedescribed below.

The drive assembly 172 may be configured to drive the take-up spoolassembly 174 so as to rotate the ribbon take-up spool 120 in a firstdirection when the take-up spool assembly is disposed in an engagedposition, as illustrated. However, the take-up spool assembly 174 may beconfigurable from the engaged position (see, e.g. FIG. 9A) to adisengaged position (see, e.g. FIG. 9B). In the disengaged position, thetake-up spool assembly 174 may at least partially decouple from thedrive assembly 172, for example at gap 181′.

When the take-up spool assembly 174 is disposed in the disengagedposition, tension in the ribbon 114 may be lost. For example, torsion inthe spring 1168 of the take-up clutch assembly 124, which biases theribbon take-up spool 120 in the first direction, may be lost because thedriven member 170 of the take-up clutch assembly may no longer berotationally coupled through the gears to the motor pinion gear 176 ofthe drive assembly 172.

The ribbon take-up spool 120, the ribbon supply spool, and the gearsconfigured to engage the ribbon take-up spool drive may be attached to aframe member 105 which is configured to move between an engaged positionand a disengaged position. The frame member 105 of the illustratedembodiment of FIG. 8 is pivotable about pivot-point 107, in thedirection of arrow 103. FIG. 8 illustrates the frame member 105 in theengaged position with the driven member 170 of the take-up spool engagedwith the drive assembly 172 via a gear train. When the frame member 105is moved along arrow 103 towards the disengaged position, the gear trainthat engages the driven member 170 of the take-up spool may bedisengaged from the drive assembly 172, as illustrated in FIG. 9B. Asillustrated, the drive assembly 172 is disposed on the base member 104such that upon frame member 105 pivoting along arrow 103, the driveassembly 172 is disengaged from the gear train driving that is engagedwith the ribbon take-up spool. The frame member 105 may be configured tobe biased toward the disengaged position such that upon opening of thelid 102, the frame member 105 moves to the disengaged position. The lid102 may include a latch which secures the lid 102 in the closed positionrelative to the base 104 such that the frame member 105 becomes securedin the engaged position when the lid 102 is closed. Thus, when the lid102 is opened, the take-up spool assembly 174 may be moved to thedisengaged position as the gears of the take-up spool assembly 174disengage from the gears of the drive assembly 172.

In order to prevent a partial or total loss of tension in the ribbon114, the printer ribbon transport assembly 112 may further comprise therotation lock mechanism 178, as illustrated in FIGS. 9A and 9B. Therotation lock mechanism 178 may include, in one embodiment, a ratchetassembly including a pawl 180 and a toothed wheel 182, a spring 186, anda lever arm 188. In some embodiments at least part of the rotation lockmechanism 178 may be mounted to the lid 102 so as to travel with thetake-up spool assembly 174 when the lid 102 is lifted. The rotation lockmechanism 178 may be configured to prevent rotation of the take-up spool120 in a second direction, which is opposite to the first direction,when the take-up spool assembly 174 is disposed in the disengagedposition.

In FIG. 9A, the gears of the take-up spool assembly 174 are depicted asbeing engaged with the gears of the drive assembly 172 at position 181.However, FIG. 9B depicts the take-up spool assembly 174 in thedisengaged position. As illustrated in FIG. 9B, when the gears of thetake-up spool assembly 174 disengaged from the gears of the driveassembly 172, the pawl 180 may be configured to engage the toothed wheel182, which may be rotationally connected to the take-up spool assembly.In particular, the toothed wheel 182 may engage a gear 184 of thetake-up spool assembly 174, although in other embodiments the pawl 180may engage a gear of the take-up spool assembly directly rather thanengaging the toothed wheel.

A spring 186 may be configured to bias the pawl 180 to engage thetoothed wheel 182 when the take-up spool assembly 174 is in thedisengaged position. For example, the rotation lock mechanism 178 mayfurther comprise a lever arm 188 coupled to the pawl 180 and configuredto cause the pawl to disengage from the toothed wheel 182 when thetake-up spool assembly 174 is in the engaged position. In oneembodiment, the printer 100 may further comprise a lever engagementsurface 190, wherein the lever arm 188 is configured to engage the leverengagement surface 190 when the take-up spool assembly 174 is in theengaged position. In some embodiments, the base structure 104 may definethe lever engagement surface 190. In the depicted embodiment, the leverarm 180 is configured to release from the lever engagement surface 190when the lid 102 is opened to thereby cause the pawl 180 to engage thetoothed wheel 182 as the take-up spool assembly 174 is configured to thedisengaged position. Accordingly, when the lid 102 is opened, therotation lock mechanism 178 may prevent rotation of the take-up spool120 and tension may thereby be maintained in the ribbon 114 even whenthe lid is opened. The ribbon supply spool 116 may maintain the tensionvia the frictional force of the clutch mechanism 122 disposed on theribbon supply spindle.

Many modifications and other embodiments of the inventions set forthherein will come to mind to one skilled in the art to which theseinventions pertain having the benefit of the teachings presented in theforegoing descriptions and the associated drawings. Therefore, it is tobe understood that the inventions are not to be limited to the specificembodiments disclosed and that modifications and other embodiments areintended to be included within the scope of the appended claims.Although specific terms are employed herein, they are used in a genericand descriptive sense only and not for purposes of limitation.

That which is claimed:
 1. A printhead assembly for use in a printingapparatus, comprising: a printhead; and a printhead support bracketcomprising: an opposed ramp surface configured for engagement by abiasing ramp of the printing apparatus; and a ribbon peel surfaceconfigured to receive a ribbon force; wherein the opposed ramp surfaceis configured to receive a biasing force from the biasing ramp, whereinthe biasing force at least partially counteracts the ribbon force. 2.The printhead assembly of claim 1, wherein the opposed ramp surfacedefines an angle between 10 and 25 degrees relative to the printheadsupport bracket.
 3. The printhead assembly of claim 1, wherein theprinting apparatus comprises a printhead biasing assembly comprising abiasing element configured to bias the biasing ramp into contact withthe opposed ramp surface of the printhead support bracket.
 4. Theprinthead assembly of claim 3, wherein the printhead biasing assemblyfurther comprising a guide member configured to guide the biasing rampon a guide path.
 5. The printhead assembly of claim 4, wherein the guidepath is configured to direct the biasing ramp toward a platen.
 6. Theprinthead assembly of claim 3, wherein the biasing ramp comprises aremovable wedge.
 7. The printhead assembly of claim 3, furthercomprising a heat sink, wherein the heat sink is coupled between theprinthead support bracket and the printhead.
 8. The printhead assemblyof claim 7, wherein the biasing assembly is configured to bias the heatsink into contact with a stop member.
 9. The printhead assembly of claim8, wherein the stop member is defined by a base structure.
 10. Theprinthead assembly of claim 1, wherein the printhead assembly is areplaceable component of the printing apparatus.
 11. A method ofaligning a printhead, comprising: receiving a ribbon force at a peelsurface of a printhead support bracket; and generating a biasing forceat the printhead support bracket to at least partially counteract theribbon force; wherein the biasing force is directed by a biasing ramp ofa biasing assembly engaging an opposed ramp surface of the printheadsupport bracket.
 12. The method of claim 11, wherein the biasing forceis directed at an angle between 10 degrees and 25 degrees relative tothe printhead support bracket.
 13. The method of claim 11, furthercomprising engaging a stop member with a heat sink coupled to theprinthead.
 14. The method of claim 11, further comprising maintaining asubstantially consistent ribbon force with a first clutch mechanismconfigured to engage a ribbon supply spool and a second clutch mechanismconfigured to engage a take-up spool.
 15. The method of claim 11,further comprising guiding the biasing ramp on a guide path with a guidemember of the biasing assembly.
 16. The method of claim 15, furthercomprising directing the biasing ramp toward a platen with the guidemember.
 17. A system for printing, comprising: a printing apparatusconfigured to print on media; a printhead; and a printhead supportbracket comprising: an opposed ramp surface configured for engagement bya biasing ramp of the printing apparatus; and a ribbon peel surfaceconfigured to receive a ribbon force; wherein the opposed ramp surfaceis configured to receive a biasing force from the biasing ramp, whereinthe biasing force at least partially counteracts the ribbon force, andwherein the printing apparatus comprises a printhead biasing assemblycomprising a biasing element configured to bias the biasing ramp intocontact with the opposed ramp surface of the printhead support bracket.18. The printhead assembly of claim 17, wherein the printhead biasingassembly further comprising a guide member configured to guide thebiasing ramp on a guide path.
 19. The printhead assembly of claim 18,wherein the guide path is configured to direct the biasing ramp toward aplaten.
 20. The printhead assembly of claim 17, wherein the biasing rampcomprises a removable wedge.